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United States Patent |
6,119,843
|
Robinson
|
September 19, 2000
|
Retractable stop assembly
Abstract
A stop assembly includes a drive arm and a stop arm with a backside
configured to direct a reaction force applied by the stop arm to the drive
arm when the stop arm engages a workpiece. The drive arm pivots between
pre-locked and unlocked positions in response to movement of the
reciprocatable member between extended and retracted positions. The motion
range includes a locked position between the pre-locked and unlocked
positions. The stop arm is pivotally mounted to the body and has a front
side for engaging a workpiece, while the backside engages the drive arm.
The stop arm backside is configured such that the reaction force has a
component normal to the drive arm plane when the drive arm is between the
pre-locked and locked positions, and such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position.
Inventors:
|
Robinson; Brian Owen (302 N. Grove, Ypsilanti, MI 48198)
|
Appl. No.:
|
243497 |
Filed:
|
February 3, 1999 |
Current U.S. Class: |
193/35A; 198/345.3 |
Intern'l Class: |
B65G 013/00 |
Field of Search: |
193/32,35 A,40
198/343.1,345.1,345.3
|
References Cited
U.S. Patent Documents
2350034 | May., 1944 | Herrington.
| |
2436941 | Mar., 1948 | Sendoykas.
| |
3116058 | Dec., 1963 | Blatt.
| |
3347542 | Oct., 1967 | Mericle, Jr.
| |
3545050 | Dec., 1970 | Blatt et al.
| |
3696756 | Oct., 1972 | Elmore, et al.
| |
3970180 | Jul., 1976 | Schlottmann et al.
| |
4184579 | Jan., 1980 | Kantarian et al.
| |
4331326 | May., 1982 | Strouss.
| |
4397386 | Aug., 1983 | Kampf.
| |
4469138 | Sep., 1984 | Satoh.
| |
4496138 | Jan., 1985 | Blatt.
| |
4576367 | Mar., 1986 | Horn et al.
| |
4637597 | Jan., 1987 | McPherson et al.
| |
4662500 | May., 1987 | Agnew.
| |
4703843 | Nov., 1987 | Dixon.
| |
4723767 | Feb., 1988 | McPherson et al.
| |
4732258 | Mar., 1988 | Burgess, Jr. | 198/345.
|
5118088 | Jun., 1992 | Sawdon.
| |
5165670 | Nov., 1992 | Sawdon.
| |
5168976 | Dec., 1992 | Kettelson | 198/345.
|
5171001 | Dec., 1992 | Sawdon.
| |
5211276 | May., 1993 | Clopton | 198/345.
|
5213189 | May., 1993 | Agnoff | 193/35.
|
5609239 | Mar., 1997 | Schlecker.
| |
5676235 | Oct., 1997 | Sam et al. | 193/35.
|
5860505 | Jan., 1999 | Metzger | 198/345.
|
5890577 | Apr., 1999 | Faisant | 193/35.
|
Primary Examiner: Bollinger; David H.
Assistant Examiner: Crawford; Gene O.
Attorney, Agent or Firm: Brooks & Kushman P.C.
Claims
What is claimed is:
1. A power operated retractable stop assembly comprising:
a body;
a reciprocatable member extending into the body and adapted to engage a
driving means, the reciprocatable member being driveable between an
extended position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
and
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a normal component that is perpendicular to the drive arm plane when
the drive arm is between the pre-locked position and the locked position
to move the drive arm toward the locked position by pivoting the drive arm
and the drive arm plane, and such that the normal component diminishes as
the drive arm pivots until the reaction force is substantially coplanar
with the drive arm plane when the drive arm is in the locked position to
cause the drive arm to remain at the locked position.
2. The stop assembly of claim 1 wherein the drive arm and the reciprocating
member are configured such that the drive arm pre-locked position
corresponds to the reciprocatable member extended position, and the drive
arm unlocked position corresponds to the reciprocatable member retracted
position, and wherein the drive arm locked position corresponds to an
intermediate position for the reciprocatable member that is between the
extended and retracted positions.
3. The stop assembly of claim 1 wherein the drive arm has an end, and the
stop assembly further comprises:
a cam roller located at the drive arm end and positioned to engage the stop
arm back side, the roller having an axis of rotation that is substantially
parallel to the drive axis and is substantially coplanar with the drive
arm plane.
4. The stop assembly of claim 1 wherein the drive arm has end, and the stop
assembly further comprises:
a cam roller located at the stop arm back side and positioned to engage the
drive arm end, the roller having an axis of rotation that is substantially
parallel to the drive axis and is substantially coplanar with the drive
arm plane.
5. A power operated retractable stop assembly comprising:
a body;
a piston and cylinder assembly;
a reciprocatable member extending into the body and connected to the piston
and cylinder assembly, the reciprocatable member being driveable by the
piston and cylinder assembly over a stroke range between an extended
position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
and
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a normal component that is perpendicular to the drive arm plane when
the drive arm is between the pre-locked position and the locked position
to move the drive arm toward the locked position by pivoting the drive arm
and the drive arm plane, and such that the normal component diminishes as
the drive arm pivots until the reaction force is substantially coplanar
with the drive arm plane when the drive arm is in the locked position to
cause the drive arm to remain at the locked position.
6. The stop assembly of claim 5 wherein the piston and cylinder assembly is
operative to urge the drive arm toward the pre-locked position and oppose
the reaction force normal component to the drive arm plane to cushion
movement of the stop arm from the pre-locked position to the locked
position, and the piston and cylinder assembly is further operative to
urge the drive arm toward the unlocked position when the reaction force is
substantially coplanar with the drive arm plane to cause the drive arm to
move out of the locked position after remaining there for a desired amount
of time and move to the unlocked position.
7. The stop assembly of claim 5 wherein the drive arm and the reciprocating
member are configured such that the drive arm pre-locked position
corresponds to the reciprocatable member extended position, and the drive
arm unlocked position corresponds to the reciprocatable member retracted
position, and wherein the drive arm locked position corresponds to an
intermediate position for the reciprocatable member that is between the
extended and retracted positions.
8. The stop assembly of claim 5 wherein the drive arm has an end, and the
stop assembly further comprises:
a cam roller located at the drive arm end and positioned to engage the stop
arm back side, the roller having an axis of rotation that is substantially
parallel to the drive axis and is substantially coplanar with the drive
arm plane.
9. The stop assembly of claim 5 wherein the drive arm has end, and the stop
assembly further comprises:
a cam roller wheel located at the stop arm back side and positioned to
engage the drive arm end, the roller having an axis of rotation that is
substantially parallel to the drive axis and is substantially coplanar
with the drive arm plane.
10. A power operated retractable stop assembly comprising:
a body;
a piston and cylinder assembly;
a reciprocatable member extending into the body and connected to the piston
and cylinder assembly, the reciprocatable member being driveable by the
piston and cylinder assembly over a stroke range between an extended
position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a component normal to the drive arm plane when the drive arm is
between the pre-locked position and the locked position to urge the drive
arm toward the locked position, and such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position to cause the drive arm to remain at the locked
position; and
a positioning guide defined by the stop assembly body, the positioning
guide being located near the stop arm and having a sloped portion that
directs an oncoming workpiece to a portion of the stop arm that is
sufficiently spaced from the stop axis such that a moment applied to the
stop arm due to the workpiece force is sufficient to overcome the driving
means and results in a cushioned stopping of the drive arm in the locked
position.
11. A power operated retractable stop assembly comprising:
a body;
a reciprocatable member extending into the body and adapted to engage a
driving means, the reciprocatable member being driveable between an
extended position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a component normal to the drive arm plane when the drive arm is
between the pre-locked position and the locked position to urge the drive
arm toward the locked position, and such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position to cause the drive arm to remain at the locked
position; and
a positioning guide defined by the stop assembly body, the positioning
guide being located near the stop arm and having a sloped portion that
directs an oncoming workpiece to a portion of the stop arm that is
sufficiently spaced from the stop axis such that a moment applied to the
stop arm due to the workpiece force is sufficient to overcome the driving
means and results in a cushioned stopping of the drive arm in the locked
position.
12. A power operated retractable stop assembly comprising:
a body;
a reciprocatable member extending into the body and adapted to engage a
driving means, the reciprocatable member being driveable between an
extended position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
and
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a component normal to the drive arm plane when the drive arm is
between the pre-locked position and the locked position to urge the drive
arm toward the locked position, and such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position to cause the drive arm to remain at the locked
position, and
wherein the drive arm and the reciprocating member are configured such that
the drive arm pre-locked position corresponds to the reciprocatable member
retracted position, and the drive arm unlocked position corresponds to the
reciprocatable member extended position.
13. A power operated retractable stop assembly comprising:
a body;
a piston and cylinder assembly;
a reciprocatable member extending into the body and connected to the piston
and cylinder assembly, the reciprocatable member being driveable by the
piston and cylinder assembly over a stroke range between an extended
position and a retracted position;
a drive arm pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis over a motion range between a pre-locked position and an unlocked
position in response to movement of the reciprocatable member, the motion
range including a locked position between the pre-locked position and the
unlocked position, and the drive arm having a central axis passing through
the drive axis to define a drive arm plane that pivots with the drive arm;
and
a stop arm pivotally mounted to the body such that the stop arm is
pivotable about a stop axis, the stop arm having a front side for engaging
a workpiece and a back side for engaging the drive arm, the stop arm being
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece,
wherein the stop arm back side is configured such that the reaction force
has a component normal to the drive arm plane when the drive arm is
between the pre-locked position and the locked position to urge the drive
arm toward the locked position, and such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position to cause the drive arm to remain at the locked
position, and
wherein the drive arm and the reciprocating member are configured such that
the drive arm pre-locked position corresponds to the reciprocatable member
retracted position, and the drive arm unlocked position corresponds to the
reciprocatable member extended position.
Description
TECHNICAL FIELD
The present invention relates to power operated retractable stop
assemblies.
BACKGROUND ART
The use of industrial retractable stop products has become wide spread, due
at least in part to high demands in the automotive and heavy equipment
industries. Conventionally, the retractable stops are powered by a linear
actuator such as an air or hydraulic cylinder, or a solenoid actuator.
A power operated retractable stop assembly typically includes a
reciprocatable rod member driven by the linear actuator, and an assembly
body secured to the driving cylinder. Some of these existing assemblies,
such as those described in U.S. Pat. No. 4,184,579, utilize a stop lever
for stopping and releasing loads traveling on a conveyor. In such an
assembly, a blocker leg is used to prevent pivoting of the stop arm
causing an uncushioned "hard" stop of loads traveling on the conveyor,
when the blocker leg is in the blocking position.
Other existing assemblies attempt to provide a cushioned stop by using
cylinder pressure to hold the stop arm in the blocking position. However,
assemblies such as these may be disadvantageous in that there is no
guarantee of a stop, and a heavy load may deflect the stop lever against
the biasing cylinder pressure and continue right past the retractable stop
without stopping. Sometimes, assemblies utilize a first mechanism for
actuating and deactuating the stop and utilize a separate shock absorber
mechanism, such as the assembly described in U.S. Pat. No. 5,168,976.
Although these existing retractable stop assemblies that provide a "hard"
stop and those assemblies that attempt to provide a cushioned stop by
using cylinder pressure have been used in many applications that have been
commercially successful, these assemblies have disadvantages. As in some
applications it may be desirable to provide a cushioned stop, assemblies
providing a "hard" stop without any cushion may not be desired. Further,
although a cushion may be desirable in some applications, because such
assemblies cannot guarantee a stopping of the load after the cushion,
these assemblies too may be undesirable. Further, assemblies utilizing a
separate shock absorber mechanism are complex and costly.
For the forgoing reasons, there is a need for an improved power operated
retractable clamp assembly.
DISCLOSURE OF INVENTION
It is, therefore, an object of the present invention to provide a power
operated retractable stop assembly with integral cushion and stopping
mechanisms.
In carrying out the above object, other objects and features of the present
invention, a power operated retractable stop assembly is provided. The
assembly comprises a body, a reciprocatable member, a drive arm, and a
stop arm. The reciprocatable member extends into the body and is adapted
to engage a driving means such as a cylinder. The reciprocatable member is
driveable between an extended position and a retracted position. The drive
arm is pivotally mounted to the body and drivingly connected to the
reciprocatable member such that the drive arm is pivotable about a drive
axis. The drive arm is pivotable over a motion range between a pre-locked
position and an unlocked position in response to movement of the
reciprocatable member. The motion range includes a locked position between
the pre-locked position and the unlocked position. The drive arm has a
central axis passing through the drive axis to define a drive arm plane
that pivots with the drive arm.
The stop arm is pivotally mounted to the body such that the stop arm is
pivotable about a stop axis. The stop arm has a front side for engaging a
workpiece and a back side for engaging the drive arm. The stop arm is
positioned to apply a reaction force to the drive arm in response to
receiving a workpiece force on the stop arm front side from a workpiece.
The stop arm backside is configured such that the reaction force has a
component normal to the drive arm plane when the drive arm is between the
pre-locked position and the locked position. The normal component of the
reaction force urges the drive arm toward the locked position. Further,
the stop arm backside is configured such that the reaction force is
substantially coplanar with the drive arm plane when the drive arm is in
the locked position to cause the drive arm to remain at the locked
position.
In a preferred embodiment, the assembly further comprises a positioning
guide defined by the stop assembly body. The positioning guide is located
near the stop arm and has a sloped portion that directs an oncoming
workpiece to a portion of the stop arm that is sufficiently spaced from
the stop axis. Thus, spacing is sufficient to apply a moment to the stop
arm due to the workpiece force that is sufficient to overcome the driving
means and results in a cushion stopping of the drive arm in the locked
position. Once in the locked position, the drive arm is locked due to the
reaction force being substantially coplanar with the drive arm plane.
Preferably, the drive arm and the reciprocating member are configured such
that the drive arm pre-locked position corresponds to the reciprocatable
member retracted position, and the drive arm unlocked position corresponds
to the reciprocatable member extended position. Alternatively, the drive
arm and the reciprocating member may be configured such that the drive arm
pre-locked position corresponds to the reciprocatable member extended
position, and the drive arm unlocked position corresponds to the
reciprocatable member retracted position.
Preferably, the assembly further comprises a cam roller located at the
drive arm end and positioned to engage the stop arm backside. The roller
has an axis of rotation that is substantially parallel to the drive axis
and is substantially coplanar with the drive arm plane. Alternatively, the
roller may be located at the stop arm backside and positioned to engage
the drive arm end.
Further, in carrying out the present invention, a power operated
retractable stop assembly comprises a body, a piston and cylinder
assembly, a reciprocatable member, a drive arm, and a stop arm. The
reciprocatable member extends into the body and is connected to the piston
and cylinder assembly. The reciprocatable member is driveable by the
piston and cylinder assembly over the a stroke range between an extended
position and a retracted position. The stop arm backside is configured
such that the reaction force has a component normal to the drive arm plane
when the drive arm is between the pre-locked position and the locked
position. Further, the stop arm backside is configured such that the
reaction force is substantially coplanar with the drive arm plane when the
drive arm is in the locked position to cause the drive arm to remain at
the locked position.
The advantages associated with embodiments of the present invention are
numerous. For example, power operated retractable stop assemblies made in
accordance with the present invention use the driving means which may be a
piston and cylinder assembly to provide a cushion when stopping a load.
The amount of cushion may be selected by choosing appropriate cylinder
operating pressure and appropriate lever arm distances between pivot
points and the force application points. Further, stop assemblies made in
accordance with the present invention, in addition to providing
cushioning, provide a "hard" stop at the end of the cushion zone. That is,
during cushioning, reaction force applied to the drive arm has a component
normal to the drive arm plane; but, once the drive arm reaches the locked
position, the reaction force is coplanar with the drive arm plane. As
such, once the stop assembly has locked, the driving means (such as a
piston and cylinder assembly) is not needed to maintain the locked
position. Although finite cylinder pressure holding force may be used to
resist/cushion movement to the locked position, alternatively, a hydraulic
cylinder with a pressure relief valve may be used.
The above object, and other objects, features and advantages of the present
invention will be readily appreciated by one of ordinary skill in the art
from the following detailed description of the best mode for carrying out
the invention when taken in connection with the accompanying drawings.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 a perspective view of a power operated retractable stop assembly
made in accordance with the present invention;
FIG. 2 is a side elevation, partially in section, of the stop assembly of
FIG. 1, showing the stop assembly in the locked position;
FIG. 3 is a side elevation, partially in section, of the stop assembly of
FIG. 1, showing the stop assembly in the pre-locked position;
FIG. 4 is a side elevation, partially in section, of the stop assembly of
FIG. 1, showing the stop assembly in the unlocked position;
FIG. 5 is a top view of the stop assembly of FIG. 1, showing the stop
assembly in the locked position;
FIG. 6 is a top view of the stop assembly of FIG. 1, showing the stop
assembly in the pre-locked position;
FIG. 7 is a top view of the stop assembly of FIG. 1, showing the stop
assembly in the unlocked position;
FIG. 8 is an end view of the stop assembly of FIG. 1, showing the stop
assembly in the locked position;
FIG. 9 is a end view of the stop assembly of FIG. 1, showing the stop
assembly in the pre-locked position;
FIG. 10 is an end view of the stop assembly of FIG. 1, showing the stop
assembly in the unlocked position; and
FIG. 11 is an alternative embodiment for a stop assembly of the present
invention, showing a cam roller on the clamp arm and an alternative
arrangement for connecting the reciprocating member to the drive arm.
BEST MODE FOR CARRYING OUT THE INVENTION
Referring to FIGS. 1 through 10 which illustrate a power operated
retractable stop assembly of the present invention, and primarily to FIGS.
2-4 which are partially in section, the preferred embodiment of the stop
assembly is generally indicated at 10. Stop assembly 10 has a body
composed of sides 12. A driving means engages body 12. A suitable driving
means is a piston and cylinder assembly, generally indicated at 14. Piston
and cylinder assembly 14 includes a cylinder 16 in which a piston 18 is
driven. Piston and cylinder assembly 14 has suitable connectors 20 and 22
for connecting to a source. Piston and cylinder assembly 14 forms a linear
actuator and may be either powered by air (or other gas) or hydraulic
media. An air powered cylinder is suitable for providing a cushioning zone
due to the compressability of gas. Alternatively, a hydraulic cylinder
with a pressure relief valve may be employed to provide a cushioning zone.
Of course, it is appreciated that compressed air may be preferred because
air sources are generally cheaper, and many times are already present at a
work site.
A reciprocatable member such as push rod 24 is driven by piston and
cylinder assembly 14 and extends into stop body sides 12. Reciprocatable
member 24 is driveable by piston and cylinder assembly 14 over a stroke
range between an extended position and a retracted position as described
further, below. Reciprocatable member 24 includes an end 26 that is
preferably adjustably secured by nut 28 and threaded portion 30 of end 26.
The nut and threads arrangement allows some adjustment of the extended and
retracted positions for reciprocatable member 24, which is preferred, but
not required.
A drive arm 32 is pivotally mounted to body 12. A pin and bearing
arrangement 34, preferably of side thrust bearings to prevent side-to-side
sliding, is used to mount drive arm 32 to body 12. Drive arm 32 is pivotal
about drive axis 36. Drive arm 32 is connected to reciprocating member end
26 by intermediate link 50. Link 50 pivotally connects to member end 26 by
pin 52, and connects to drive arm 32 with pin 34. As pin arrangements 52
and 54 will move with respect to body 12 during operation, pin
arrangements 52 and 54 only extend within the clamped sides and preferably
are needle bearings on hardened shafts. Accordingly, pin and bearing
arrangement 34 and drive arm 32 are affixed to clamp body 12.
Drive arm 32 is pivotable about drive axis 36 over a motion range between a
pre-locked position (reference numeral 56, FIG. 3) and an unlocked
position (reference numeral 60, FIG. 4). Further, the motion range
includes a locked position (reference numeral 32, FIG. 2) between the
unlocked and pre-locked positions. The reciprocatable member is in the
retracted position 58 (FIG. 3) when the drive arm is in the pre-locked
position 56 (FIG. 3). The reciprocatable member is in the extended
position 62 (FIG. 4) when the drive arm is in the unlocked position 60
(FIG. 4). The reciprocatable member is at an intermediate position 26
(FIG. 2) when the drive arm is in the locked position 32 (FIG. 2).
As described above, the drive arm moves over its motion range in response
to movement of the reciprocatable member. Drive arm 32 has a central axis
64 passing through drive axis 36 to define a drive arm plane that pivots
with the drive arm. The drive arm plane is the plane defined by central
axis 64 and pivot axis 36 that, when viewing FIG. 2, is perpendicular to
the page. The drive plane rotates as the drive arm rotates, which may be
observed by referring to FIG. 3. In FIG. 3, the drive plane is again
perpendicular to the page, but has rotated slightly clockwise from the
position of the drive plane of FIG. 2.
Of course, as mentioned previously, although in a preferred embodiment of
the present invention, the extended reciprocating member corresponds to
the unlocked position for the drive member, and the retracted
reciprocating member corresponds to the pre-locked position for the drive
member, an alternative arrangement is contemplated and is shown in FIG.
11, later described below. In particular, it is preferred that the
retracted reciprocatable member corresponds to the pre-locked position
such that when the drive member is urged to the locked position, maximum
available force may be applied to piston 18 within piston and cylinder
assembly 14 to unlock the assembly. That is, in a piston and cylinder
assembly of a particular operating pressure, more force may be applied
when extending piston rod 24 than when retracting piston rod 24. This is
because the attachment of piston rod 24 to piston 18 takes up some of the
available surface area and resultantly reduces the amount of force
available to move piston 18 towards the opposite side of where piston rod
24 is attached thereto for a given operating pressure.
Stop assembly 10 also includes a stop arm 70. Stop arm 70 is affixed to
body 12 by pin and bearing assembly 72, which extends through clamp body
12 and which preferably includes side thrust bearings to prevent
side-to-side sliding. Stop arm 70 is pivotable about a stop axis 74. Stop
arm 70 has a front side 76 for engaging a workpiece, such as workpiece 84
(FIG. 3). Stop arm 70 has a backside 78 for engaging drive arm 32.
Based upon a variety of design parameters, such as cylinder operating
pressure or pressure relief valve configuration, it is usually desirable
that when a workpiece contacts stop arm 70, that workpiece contacts stop
arm 70 at a point sufficiently spaced from pivot axis 72. A sufficient
spacing from pivot axis 72 assures that a reasonable moment is applied to
stop arm 70 to push drive arm 32 over the cushioning zone against the bias
of piston and cylinder assembly 14. Of course, positioning guide 80 is
preferred but not required. Positioning guide 80 is part of body assembly
12 and is affixed to the stop sides by bolts 82.
By appropriately implementing a positioning guide, it is to be appreciated
that, as best shown in FIG. 3, workpiece 84 contacts stop arm 70 at a
contact point sufficiently spaced from pivot axis 74. The sloped portion
of the positioning guide, which is located near stop arm 70, directs an
oncoming workpiece (shown in phantom at 86, FIG. 3) to a contact point
sufficiently spaced from stop axis 74. As such, a cushion stopping of the
drive arm in the locked position occurs. Stop arm 70 is positioned to
apply a reaction force to drive arm 32 in response to receiving a
workpiece force on front side 76 from a workpiece 84.
As best shown in FIG. 3, stop arm backside 78 is configured such that a
reaction force applied by stop arm backside 78 to drive arm 56 in response
to the force of workpiece 84 on stop arm 70 has a component 100 that is
normal to the drive arm plane when the drive arm is between the pre-locked
position and the locked position. Because drive axis 36 lies in the drive
arm plane, forces normal to the drive arm plane urge the drive arm toward
the locked position. As such, configuring stop arm backside 78 such that
the reaction force has a component normal to the drive arm plane when the
drive arm is between the pre-locked position and the locked position,
causes the drive arm to be urged to the locked position, whenever a
workpiece contacts stop 70 and the drive arm is between the pre-locked
position 56 and the locked position 32.
As best shown in FIG. 2, when the drive arm reaches the locked position 32,
the configuration of stop arm backside 78 causes the reaction force 102
applied by stop arm backside 78 to drive arm 32 to be substantially
coplanar with the drive arm plane. Because drive arm axis 36 lies in the
drive arm plane, substantially coplanar reaction forces are opposed by pin
and bearing assembly 34, and do not cause drive arm 32 to rotate out the
locked position.
Advantageously, pin and bearing assembly 34 hold the stop assembly in the
locked position against the force of any load or workpiece, and if
desired, piston and cylinder assembly 14 need not be relied on to maintain
the locked position for the retractable stop. After drive arm 32 and stop
arm 70 have remained in the locked positions for a desired amount of time,
piston and cylinder assembly 14 may be actuated to urge the drive arm to
the unlocked position 60 (FIG. 4), allowing stop arm 70 to pivot and allow
workpiece 84 to pass.
Advantageously, embodiments of the present invention provide a cushioning
zone between the pre-locked and locked positions in which the amount of
cushion may be determined by selecting appropriate lever arm lengths,
pivot point positions, utilization of a positioning guide, and selection
of actuator operating pressures or pressure relief valve configuration.
Further, it is to be appreciated that embodiments of the present
invention, after the cushioning zone, provide a "hard" stop.
Advantageously, the hard stop directs all force from the workpiece in a
direction coplanar with the drive arm plane such that this reaction force
is received by pin and bearing assembly 34 almost in its entirety.
In a preferred embodiment of the present invention, a cam roller 90 is
located at the end of the drive arm and is positioned to engage stop arm
backside 78. Roller 90 has an axis of rotation 92 that is substantially
parallel to drive axis 36 and is substantially coplanar with the drive arm
plane. Of course, alternatively, the roller may be provided on stop arm
70, instead, if desired, but it is preferred that roller 90 be located at
the end of the drive arm. Preferably, in compressible gas type cylinder
embodiments, backside surface 78 includes a portion 108 that is configured
to follow a radius from the drive arm axis 36 that extends to the contact
point of roller 90 and backside surface 78. As such, the drive arm may
slightly bounce or overshoot as the stop arm moves to the locked position
without disturbing the stop arm. A small bump 110 marks the end of the
overshoot roll zone. In a construction using an air cylinder (to allow gas
compressability), the inventor has observed bounce or overshoot of about
0.50 in (1.3 cm) to 0.75 in (1.9 cm). As such, in that example, a radiused
portion (overshoot roll zone) that extends over an arc length of about
0.75 in (1.9 cm) is suitable to allow recovery from reverberations in the
air column.
With reference now to FIG. 11, several alternatives for implementing
specific features of the present invention are described. A power operated
retractable stop assembly having several alternative features is generally
indicated at 120. Assembly 120 has a body 122 connected to a piston and
cylinder assembly 124. Reciprocatable member 126 and drive arm 128 are
configured such that the extended position for retractable member 126
corresponds to the pre-locked position for a drive arm 128, and the
retracted position for reciprocatable member 126 corresponds to the
unlocked position for the drive arm 128. This is achieved by connecting
reciprocatable member 126 to drive arm 128 with a link 130 to a pivot pin
connection 132 that is on an opposite side of pin and bearing assembly 134
and pivot axis 136 than stop arm backside 138. In another alternative
feature, a roller 140 having an axis of rotation 142 is connected to stop
arm 144, as suggested previously. Further, an alternative, long stop arm
is shown in phantom at 112. Further, preferably in all embodiments,
radiused portion 114 on the stop arm rides on the drive arm to lift the
stop arm from the unlocked position.
While embodiments of the invention have been illustrated and described, it
is not intended that these embodiments illustrate and describe all
possible forms of the invention. Rather, the words used in the
specification are words of description rather than limitation, and it is
understood that various changes may be made without departing from the
spirit and scope of the invention.
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